I have a function that returns an IO action,
f :: Int -> IO Int
I would like to compute this function in parallel for multiple values of the argument. My naive implementation was as follows:
import Control.Parallel.Strategies vals = [1..10] main = do results <- mapM f vals let results' = results `using` parList rseq mapM_ print results'
My reasoning for this was that the first
mapM binds something of type
IO [Int] to
results' applies a parallel strategy to the contained list, and the
mapM_ finally requests the actual values by printing them - but what is to be printed is already sparked in parallel, so the program should parallelize.
After being happy that it does indeed use all my CPUs, I noticed that the program is less effective (as in wall clock time) when being run with
+RTS -N8 than without any RTS flags. The only explanation I can think of is that the first
mapM has to sequence - i.e. perform - all the IO actions already, but that would not lead to ineffectivity, but make the
N8 execution as effective as the unparallelized one, because all the work is done by the master thread. Running the program with
+RTS -N8 -s yields
SPARKS: 36 (11 converted, 0 overflowed, 0 dud, 21 GC'd, 4 fizzled), which surely isn't optimal, but unfortunately I can't make any sense of it.
I suppose I've found one of the beginner's stepping stones in Haskell parallelization or the internals of the IO monad. What am I doing wrong?
f n is a function that returns the solution for Project Euler problem n. Since many of them have data to read, I put the result into the IO monad. An example of how it may look like is
-- Problem 13: Work out the first ten digits of the sum of one-hundred 50-digit numbers. euler 13 = fmap (first10 . sum) numbers where numbers = fmap (map read . explode '\n') $ readFile "problem_13" first10 n | n < 10^10 = n -- 10^10 is the first number with 11 digits | otherwise = first10 $ n `div` 10